• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
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  • 优先权
    • 专利摘要:
    NUCLEAR REACTOR CORE LOADING AND OPERATION STRATEGIES ABSTRACT OF THE DISCLOSURE Cores include different types of control cells in different numbers and positions. A periphery ofthe core just inside the perimeter may have higher reactivity fuel in outer control cells, and lowerreactivity cells may be placed in an inner core inside the inner ring. Cores can include about halffresh fuel positioned in higher proportions in the inner ring and away from inner control cells.Cores are compatible With multiple core control cell setups, including BWRs, ESBWRs,ABWRs, etc. Cores can be loaded during conventional outages. Cores can be operated Withcontrol elements in only the inner ring control cells for reactivity adjustrnent. Control elements inouter control cells need be moved only at sequence exchanges. Near end of cycle, reactivity inthe core may be controlled With inner control cells alone, and control elements in outer control cells can be fully Withdrawn. 22
    公开号:SE1350723A1
    申请号:SE1350723
    申请日:2013-06-13
    公开日:2013-12-24
    发明作者:Gregory J Pearson;Atul Arun Karve
    申请人:Global Nuclear Fuel Americas;
    IPC主号:
    专利说明:

    for neutron currents during power operation, ie they have not been used, while used fuel bundles have received such a release, typically over one or more fuel cycles extending 1-2 years. As such, the fuel bundles typically used have an exposure, or consumption, of several GWd / ST.
    New fuel bundles can have different starting enrichment degrees of fissile material content. For example, in some BWR constructions, externally enriched bundles (shown with cross-sectional fill) may comprise about 4.3% uranium-235 fuel and inner enriched bundles (shown with diagonal fill) may comprise about 4.2% uranium. 235 fuel. Varying degrees of enrichment, such as that shown in Fig. 2, may allow a flatter, radial power profile in the core and / or obtain other operating effects. Furthermore, in some BWR constructions, the bundles may also have varying distributions and concentrations of combustible toxins / neutron absorbers to suppress reactivity and optimize operating characteristics. As shown in Fig. 2, at start-up, nuclear fuel hearths according to the prior art comprise an outer circumferential ring with used fuel bundles which surround an inner circumferential ring with new, enriched fuel bundles. A central area may include 50% or more new fuel bundles to maximize the content of new fuel bundles over a more even distribution, allowing longer operating cycles with shorter downtime.
    In prior art BWRs, cruciform guide blades 60 extend centrally between arrays of four fuel bundles to absorb neutrons and control the nuclear chain reaction in the core. As shown in Fig. 2, the groupings of four fuel bundles, between which the guide blades extend, are identified with a bold contour as guided bundles or control cells. The bundles within the controlled bundle groups conventionally have a surface closest to a guide blade used during the fuel cycle; such bundles are referred to as controlled bundles and their positions as controlled positions in control bundles of four bundles. Different guide blades in different guide cells, usually four or five per quadrant, are conventionally pushed in and retracted alternately in different and complex guide blade sequences to control reactivity and power distribution and spread guide blade use across several different blades and new fuel bundles within the core.
    As shown in Fig. 2, to maximize the number of new fuel bundles used in a longer cycle over an even core distribution, several new fuel bundles can be placed in controlled positions adjacent to used guide blades within the inner region of the core. Due to the conventional use of guide blades, all new fuel bundles in the central core part can be controlled - which have direct exposure to guide blades actively moved for fine-tuning of reactivity - throughout an entire fuel cycle. Use of new fuel bundles in controlled positions causes several problems including corrosion and duct bending that get worse in later cycles, and a need to perform complex and / or low power guide blade sequence changes due to this location which degrades the plant economy. Some prior art fuel hearths have avoided this problem by using control cell core charging strategy, where only used fuel bundles are located closest to used guide blades, resulting in fewer new bundles being used in the central part of the core and shorter operating cycles.
    EXPLANATION Exemplary embodiments include core cores with at least two control cell types that differ in total reactivity. The different control cell types can be placed in numbers and / or positions to improve fuel and core performance. Exemplary hearths may include an outermost region with lower reactivity fuel bundles, an inner circumferential region edging the outer circumferential region and having higher reactivity fuel bundles and at least portions of the outermost control cells, and an inner hearth edging the inner circumferential region and having inner control cells with only fuel bundles of lower reactivity.
    The lower reactivity fuel bundles may be used and the higher reactivity bundles may be new, for example the outer control cells may comprise two new fuel bundles and the inner control cells may comprise only used fuel bundles. However, the reactivity differences can also be obtained by fuel enrichment variation, the presence of combustible poison, etc. In an example with a conventional BWR, the inner circumferential region may be three bundles thick, most of which may be fuel bundles of higher reactivity, and the outer circumferential region may be three cut thick. In this example, there may be thirteen internal control cells.
    Exemplary embodiments are not limited to BWRs or particular locations, but are compatible with any type of core control cell setup, including control cells formed with control rods or cross-shaped control blades having four fuel bundles located in each corner of the blades. Different core geometries can be easily formed with the exemplifying ones in an ESBWR, the internal embodiments, e.g. the core area have twenty-five internal control cells.
    Exemplary methods include creating and / or operating core foci with multiple types of control cells. For example. a hard can be charged to form a hard according to an exemplary embodiment. In the exemplary methods, control elements can only be moved in the internal control cells to control hard reactivity, except for sequence changes after several weeks or months of operation, such as after 3 GWd / ST. In such a sequence change, a simple coarse movement of the control elements into the outer control cells can be performed to resume control of day-to-day reactivity with the inner control cells. At the end of a cycle, when the reactivity is lowest, the reactivity in the core can be controlled only by the inner control cells, and the control elements in the outer control cells can be completely retracted.
    Exemplary embodiments and methods can provide high (approximately 50%) new fuel cell volumes for each cycle, enabling longer cycles and better plant economies. Exemplary methods and embodiments further provide high power density and low leakage by segregating fuel types by reactivity in the periphery and the inner parts of the hard.
    Exemplary methods and embodiments may further enable simplified and non-intermittent movement of control elements in the inner hard to fully control the reactivity without causing negative control element and well mud interactions.
    BRIEF DESCRIPTION OF THE DRAWINGS Exemplary embodiments will become more apparent by describing, in detail, the accompanying drawings, in which like elements are represented by like reference numerals, which are given for illustrative purposes only and are not intended to limit the scope which they describe.
    Fig. 1 is an illustration of the prior art fuel bundles loaded in a hearth having cruciform blades for guide elements.
    Fig. 2 is a prior art quadrant map of a commercial nuclear reactor core.
    Fig. 3 is a quadrant map of a core core according to an exemplary embodiment.
    Fig. 4 is a quadrant map of another embodiment of a core core.
    DETAILED DESCRIPTION This is a patent document, and generally broad rules of interpretation should be used when reading and understanding it. Everything described and shown in this document is an example of a patent subject which falls within the scope of the appended claims. Each specific structural and functional detail described herein is for descriptive purposes only as to how exemplary embodiments or methods may be formed and used. Several embodiments not described herein fall within the scope of protection; as such, the claims may be expressed in many alternative forms and should not be limiting in interpretation to only the embodiments described herein.
    It is to be understood that, etc., although the terms first, second, may be used herein to describe various elements, these elements should not be limited by these terms. These terms are used only to distinguish one element from one, a first element may be termed a second another. For example. elements and similarly, a second element may be referred to as a first element, without departing from the scope of the exemplary embodiments. As used herein, the term "and / or" shall include any and all combinations of one or more of the associated enumerated features. It is to be understood that when an element is referred to as being "connected", "connected", "fitted", "attached" ", Or" attached "to or to another element, it may be directly connected or connected to the other element or intermediate elements may be present. In contrast, when an element is referred to as being "directly connected" or "directly connected" to another element, no intermediate elements are present. Other words used to describe the relationship between elements should be interpreted "between" versus "directly in a similar way (eg between", "adjacent" versus "directly adjacent", etc.).
    Similarly, a term such as "communicatively connected" includes all variations of information exchange paths between two devices, including intermediate devices, networks, etc. connected wirelessly or not.
    As used herein, the singular forms "one", "one" and "the" are intended to include both singular and plural forms, unless the language expressly indicates otherwise with words such as "only", "only", and / or "one". It is further understood that the terms "includes", and / or "includes", when used herein, specify the presence of the stated features, steps, operations, elements, ideas and / or components, but do not exclude the very presence or addition of one or more several other features, steps, operations, elements, components, ideas, and / or groups thereof.
    It should also be noted that the structures and operations described below may occur in a different order from that described and / or shown in the figures. For example. two operations and / or figures shown in order can actually be performed simultaneously or can sometimes be performed in the opposite order, depending on the functionality / actions involved. Similarly, individual operations within exemplary methods described below may be performed repetitively, individually, or sequentially, to create feedback loops or series of operations in addition to the simple operations described herein. It is to be understood that each embodiment having features and functionality falling within is described below, in each executable combination, the scope of the exemplary embodiments.
    Applicants have realized problems that exist in several different types of nuclear fuel centers with control element placement near certain fuel bundles. In particular, the applicant has identified that while maximizing new fuel within a nuclear fuel hard at each start of a cycle will allow longer cycle times and reduce dead time intervals, such maximization may also force new fuel bundles to be placed directly adjacent control elements, which can cause multiple fuel problems. lifetime, including corrosion, duct blade interference, and PCI (pellet cladding interaction). Applicants have further realized that control cell core handling techniques, where new fuel bundles are not placed directly adjacent to control elements, limit the amount of new fuel that can be placed within a core as well as limit the placement of new fuel in optimal power management positions, resulting in reduced consumption / efficiency and shorter operating cycles.
    Exemplary embodiments and methods below address these and other problems identified by applicants in related nuclear fuel management technologies for a wide range of nuclear power plants.
    Exemplary Embodiments Exemplary embodiments of the invention include nuclear fuel cores having fuel of higher reactivity in lower proportions adjacent control elements. Fuel of lower reactivity is placed in a larger proportion next to control elements, while the total fuel content and the operating life of the core are allowed to be mainly maintained. Exemplary embodiments form two or more types of positions which are subject to direct control element exposure - a larger number of controlled positions of a first type having a higher population of spent and / or fuel of lower enrichment; and a smaller number of controlled positions of a second type having a higher population of new and / or fuel of higher enrichment. Particular exemplary embodiments describe how this configuration can be obtained for different types of core structures discussed below, with the understanding that specific locations of different types of controlled positions in different areas in different exemplary embodiments may be varied based on core structure and reactivity requirements. It is further understood that each particular plant type, fuel type, enrichment degree, exposure level and / or control element configuration described in these exemplary embodiments is not limiting but merely provides examples of the breadth of nuclear reactor technologies within which the exemplary embodiments may be implemented.
    Exemplary methods for forming and using exemplary embodiments are described below.
    Fig. 3 is a quadrant map of an exemplary embodiment of a fuel core 100; for example, Fig. 3 may be an initial charge map for a particular cycle. The core 100 may be useful in existing boiling water reactors, for example, the core 100 may be useful in similar facilities such as the related fuel core charging strategy of Fig. 2.
    As shown in Fig. 3, the core 100 may include a typical BWR fuel core geometry, such as e.g. and 17- flash radius quadrant.
    The core 100 of the exemplary embodiment can be visualized in three areas: an outer perimeter 120, an inner perimeter 130, and an inner core 140. The outer perimeter 120 may be up to three fuel bundles thick from one edge of the reactor core and includes most commonly used fuel rods. 111 (not filled). Fuel rods 111 used are bundles that have experienced a consumption in previous operating cycles or have been otherwise exposed to neutron flux or have significantly lower reactivity than new fuel bundles.
    The inner circumference 130 may be up to three fuel bundles thick and includes a larger proportion of new fuel bundles 110 of higher degree of enrichment (cross-filled). The inner core 140 comprises the remainder of the core within the inner periphery 130 and comprises a mixture of new fuel bundles 112 of lower enrichment (diagonal filling) and used fuel bundles 111. New fuel bundles 11 110 and 112 may have little or no previous neutron current exposure compared to used fuel bundles 111. Eg. For example, new fuel bundles 110 and 112 may be newly manufactured bundles previously unused in core operation. New fuel bundles 110 of higher enrichment degree and new fuel bundles 112 of lower enrichment degree may differ in degree of enrichment of fissile material to any extent required for curing operation 100 and optimization. For example. For example, the new enrichment fuel rods 110 may contain 4.3% uranium-235 fuel and the new enrichment fuel bundles 112 may comprise approximately 4.2% uranium-235 fuel. The fuel bundles 110 and 112 may each also have different distributions and concentrations of combustible absorber.
    In other exemplary embodiments, use fuel bundles 111, new fuel bundles 110 of higher enrichment, and new fuel bundles 112 of lower enrichment may be exchanged for fuel bundles having the same age but varying initial enrichment and combustible absorber concentration to obtain the same reactivity differences as between bundles 110, 111 and 112. the exemplary embodiment of the core 100. Similarly, differences in reactivity can be obtained using bundles of the same initial degree of enrichment but having three different operating exposure levels, such as new, used in one cycle or used in two cycles instead of higher bundle fuel bundles 110, the new fuel bundles 112 of lower enrichment and the spent fuel bundles 111. Furthermore, reactivity and enrichment differences between all new fuel bundles 110 and 112 may be non-existent or minimal such as where a single type of fuel and enrichment is used throughout an entire exemplary hearth having only different aged bundles of fuel.
    Comparing Figures 2 and 3, it can be seen that the core 100 according to the exemplary embodiment includes more new fuel bundles in the inner peripheral region 130 and does not follow a strict checkerboard pattern for new and used fuel bundles in the inner core 140. In this way, the core 100 may according to the exemplary embodiment comprise substantially the same proportion of new fuel bundles 110 and 112 and / or fissile mass and reactivity as prior art cures charged for a maximum operating cycle length. Instead of a strict chessboard alternating between used fuel bundles 111 and new fuel bundles 112 of lower enrichment in the inner core 140, the core 100 according to the exemplary embodiment comprises some groupings of fuel bundles comprising more used bundles 111.
    As can be seen in Fig. 3, four used fuel bundles 111 can be grouped around a guide blade to form a priority control cell 142 which includes fewer new fuel bundles than non-priority control cells 141. For example. As shown in Fig. 3, priority control cells 142, shown in solid black line surrounding the fuel positions thus controlled, may include only used fuel bundles 111.
    The priority control cells 142 may be the innermost control cells within the inner region 140. Non-priority control cells 141, shown in dashed black, surrounding the fuel bundle positions so controlled may comprise a mixture of used fuel bundles 111 and new prior art similar bundles 112 in Fig. 1 and may be 13 located closer to or in the inner periphery 130, outside the priority control cells 142.
    Fig. 4 is a quadrant map of a fuel core 200 according to an exemplary embodiment; for example Fig. 4 may be an initial charge map for a particular cycle. The core 200 in the example of Fig. 4 may be useful in an ESBWR (Economic Simplified Boiling Water Reactor). As shown in Fig. 4, the core 200 may include a typical ESBWR fuel core geometry, such as a 19-pin radius quadrant.
    The core 200 according to the exemplary embodiment can be visualized in three areas: an outer circumference 220, an inner circumference 230, and an inner core 240. The outer circumference 220 may be up to three fuel bundles thick from one edge of the reactor core and include at most once use fuel bundles 213 (dashed fill) and twice use fuel bundles 211 (no fill). Fuel bundles 211 and 213 used are bundles that have experienced consumption in previous operating cycles or have otherwise been exposed to neutron current or have significantly lower reactivity than new fuel rods. For example. The single-use fuel bundle 213 may have about 15-23 GWd / ST exposure from a single two-year operating cycle in known ESBWR cores, and the dual-use fuel bundle 211 may have multiple uses, such as -40 GWd / ST exposure.
    The inner circumference 230 may be one to three fuel bundles thick and may comprise a larger proportion of new fuel bundles 210 of higher degree of enrichment (cross-filled). The inner core 240 comprises the remainder of the core within the inner circumference 230 and comprises a mixture of substantially new fuel bundles 212 of lower enrichment (diagonal filling) and once used fuel bundles 213. New fuel bundles 210 and 212 may have little or no previous neutron current exposure compared to with used fuel bundles 211 and 213. Eg. For example, new fuel bundles 210 and 212 may be newly manufactured bundles previously unused in core operation. New fuel bundles 210 of higher enrichment degree and new fuel bundles 212 of lower enrichment degree can differ in fissile material enrichment degree by the degree required for operation and optimization of the core 200. Eg. For example, new fuel bundles 210 of higher enrichment may contain 4.3% uranium-235 fuel and new fuel bundles 212 of lower enrichment may contain approximately 4.2% uranium-235 fuel. Fuel bundles 210 and 212 can each of different distributions and concentrations of combustible absorber as well.
    In other exemplary embodiments, twice used fuel bundles 211, once used fuel bundles 213, new fuel bundles 210 of higher enrichment degree, and new fuel bundles 212 of lower enrichment degree may be replaced with fuel bundles having the same age but varying initial enrichment degree and combustible absorber concentration to obtain the same concentrations. as between the bundles 210, 211, 212 and 213 in the core 200 in the exemplary embodiment. Similarly, the reactivity differences can be obtained by using bundles of the same initial enrichment degree but having three different operating exposure levels, such as new, use once, or use twice instead of the new fuel bundles 210 of higher enrichment degree, the new fuel bundles 212 of lower enrichment degree and the fuel bundles 211 and 213 used.
    Furthermore, the reactivity and enrichment degree differences between new fuel bundles 210 and 212 may be non-existent or minimal so that where a single fuel type and enrichment degree are used throughout the core, different aged fuel bundles have.
    The core 200 according to the exemplary embodiment may comprise substantially the same amount of new fuel bundles 210 and 212 and / or fissile mass as the prior art ESBWR core charged for maximum operating cycle length.
    The core 200 of the exemplary embodiment includes certain arrays of fuel bundles that include multiple used bundles 211 and / or 213. As can be seen in Fig. 4, four single-use fuel bundles 213 may be grouped around a guide blade to form a priority cell 242 that includes smaller ones. fuel bundles and less reactivity than non-priority control cells 241.
    For example. As shown in Fig. 4, priority control cells 242, shown in solid black line around the bundle positions so controlled, may include only once used fuel bundles 213.
    Priority control cells 242 may be the innermost control cells within the inner region 240. The non-priority control cells 241, shown in dashed black line surrounding the bundle positions so controlled, may comprise a mixture of used fuel bundles 211 and 213 and new bundles 112 and may be located closer to or in the inner circumference 230.
    Hearths according to exemplary embodiments are useful with fuel compositions described in our co-owned application 12 / 843,037 filed July 25, 2010 and entitled "OPTIMIZED FUEL ASSEMBLY CHANNELS AND METHODS OF CREATING THE SAME", which is hereby incorporated herein by reference in its entirety. For example. For example, fuel bundles to be placed in controlled positions in hearths according to exemplary embodiments can use channels with Zircaloy-4 to further protect against shadow corrosion.
    Other exemplary working cores may be useful in advanced boiling water reactors, other light and heavy water reactors, or any nuclear reactor having nuclear chain reaction control structures extending into the core useful for controlling reactivity, with modifications of size and initial degrees of enrichment made for the particular core type. and control element placement.
    Exemplary Methods Exemplary methods include charging and / or operating core cores. Exemplary methods may benefit particularly from core cores being charged as described above in the exemplary embodiments, but it is to be understood that exemplary methods and embodiments may be used separately.
    During an operating downtime or other time when the core is available for charging, an operator or other party may charge a core to obtain charging patterns consistent with those described in the embodiments exemplified above, e.g. Existing fuel bundles can be moved to unused fuel locations based on their age, degree of enrichment, and / or reactivity. Such movement can open a number of positions around an inner circumference and non-primary controlled positions within the inner core. A desired number of oldest or least functional fuel bundles can be moved from the core. New fuel bundles can be picked up and installed in places that are empty due to the moved fuel based on degree of enrichment or other parameters.
    Such movement can create a fuel core similar to the exemplary embodiments described above or related embodiments.
    During operation of a core, control elements can be used to control the core chain reaction. For example. In prior art BWRs, a cross-shaped guide blade can extend between four adjacent bundles in a control cell to control reactivity. Exemplary methods include using only the control elements directly adjacent to the fuel bundles which have relatively low reactivity and / or which have been previously used and are not entirely new, day-to-day reactivity control within a core. In exemplary methods, the control elements directly adjacent to new or fuel bundles of higher reactivity are relatively stationary and are used only for coarse reactivity adjustments at a few set points during the fuel cycle; these control elements can be completely moved from the core - ie. not used at all for reactivity control - during the latter part of the cycle.
    As a specific exemplary method in connection with the exemplary embodiment of Fig. 4, an operator or other party may charge an ESBWR core 200 to create priority control cells 242 comprising only spent fuel associated with the guide blades in a central region of the inner core 240 of core 200. Non-priority control cells 241 comprising some new and / or high reactivity fuel bundles are created at guide blade positions closer to or in the inner peripheral area 230, outside the priority control cells 242. 18 During sequence change intervals occurring at approximately every 3 GWd / ST of operation, e.g. ., the guide blades of a non-priority cell 241 can be moved to a desired coarse reactivity control position. Otherwise, the guide blades in non-priority cells 241 are not required to be moved for reactivity control, and the guide blades only in priority control cells 242 can be moved for finer reactivity control during the sequence. During the last quarter of operation, at about 15 GWd / ST cycle average exposure, for example, the guide blades in non-priority cells 241 can be fully retracted and are not necessary for reactivity control. At all points during the cycle, the guide blades associated with priority cells 242 can be moved freely to perform fine adjustments of the core reactivity. During the last cycle quarter, the guide blades in priority cells 242 only can be used to control the core reactivity; i.e. the guide blades in priority cells 242 may be the only blades within the core 200 after about 15 Gwd / ST.
    Exemplary embodiments and / or methods may provide fuel cores in existing and future designed reactors with sufficiently high refueling sizes of new fuel to create longer operating cycles of higher power densities, while reducing or eliminating problems associated with new or higher reactivity fuels adjacent to the control elements. Placing new fuel in larger numbers around an inner circumference of the core and in a limited number of controlled positions can provide a position leakage hearth having multiple inner controlled positions that does not include new or higher PCI fuel reactivity. In this way, shadow corrosion (pellet 19 cladding interaction) and resulting channel distortions and negative control channel interactions can be reduced by avoiding placing the newest and / or fuel bundles of highest reactivity closest to the active control elements. In addition to longer operating cycle compatibility, higher power density, lower leakage, and reduced duct distortion, exemplary embodiments and / or methods may allow nuclear fuel cores to be operated with simplified control maneuvers; in particular, exemplary embodiments and methods may allow only a subset of the control elements to be used for immediate, fine reactivity control and reduce a number of overall control element sequences and changes throughout the operating cycle and / or reduce any need for lower power during such complicated changes. These and other advantages and solutions to the newly identified curing operation problems are addressed by various exemplary embodiments and methods described above.
    Exemplary embodiments and methods described above may, as will be appreciated by one skilled in the art, be varied and replaced by routine experimentation while still falling within the scope of the appended claims. For example. For example, a number of different nuclear fuel types and core designs can be compatible with exemplary embodiments and methods simply by charging and operating strategies - and without any core geometry or structural changes - and fall within the scope of the requirements. Such variations shall not be construed as a departure from the scope of these requirements.
    权利要求:
    Claims (20)
    [1] 1. l. A nuclear core comprising:a first type of control cell; anda plurality of a second type of control cells, wherein,the first type and the second type of control cells include only fuel bundlesdirectly exposed to moveable reactivity control elements,the first type of control cell has a combined reactivity higher than a combinedreactivity of the second type of control cell, andthere are more second type of control cells than the first type of control cells in the core.
    [2] 2. The nuclear core of claim l, wherein each fiael bundle of the second type of control cell is bumt, and Wherein at least one fuel bundle of the first type of control cell is fresh.
    [3] 3. The nuclear core of claim l, further comprising: an outer peripheral region extending from an edge of the core toward a center of the core; an inner peripheral region extending from the outer peripheral region toward the centerand including at least one fuel bundle in the first type of control cell; and an inner core region extending from the inner peripheral region toward the center and including at least one of the second type of control cell.
    [4] 4. The nuclear core of claim 3, Wherein the inner peripheral region is three bundles thick and includes a majority of fresh fuel bundles. 17
    [5] 5. The nuclear core of clairn 4, Wherein the outer peripheral region is three bundlesthick, and Wherein the inner peripheral region includes fuel bundles With the highest reactivity in the core.
    [6] 6. The nuclear core of claim 1, Wherein the rnoveable reactivity control elements arecruciforrn control blades, and Wherein the first type of control cell and the second type of control cell include only four fuel bundles positioned in each corner of one of the cruciforrn control blades.
    [7] 7. The nuclear core of claim 1, Wherein the core is a Boiling Water Reactor core, and Wherein the core includes at least thirteen control cells of the second type.
    [8] 8. The nuclear core of clairn 7, Wherein the core is an Economic Sirnplified Boiling Water Reactor core, and the core includes at least twenty-five control cells of the second type.
    [9] 9. The nuclear core of clairn 7, Wherein the inner periphery includes fresh fuel bundles having a higher fuel enrichment than the at least one fuel bundle of the first type of control cell.
    [10] 10. The nuclear core of clairn 1, Wherein the first type of control cell includes at least two fresh fuel bundles and the second type of control cell includes no fresh fuel bundles. 18
    [11] 11. A method of operating a nuclear core, the method comprising:loading an outer peripheral region extending from an edge of the core toward a center ofthe core with bumt fuel bundles;loading an inner peripheral region extending from the outer peripheral region toward thecenter With at least one fuel bundle in a first type of control cell; andloading an inner core region extending from the inner peripheral region toward the centerwith at least one bundle in a second type of control cell, wherein,the first type and the second type of control cells include only fuel bundlespositioned directly adjacent to moveable reactivity control elements, andthe first type of control cell includes at least one fuel bundle having a reactivity that is substantially higher than a reactivity of each fuel bundle of the second type of control cell.
    [12] 12. The method of claim 11, further comprising:moving control elements in only the second type of control cell to control reactivity in the core for a plurality of operating days.
    [13] 13. The method of claim 12, further comprising:withdrawing control elements in the first type of control cell only after approximately 3 GWd/ST.
    [14] 14. The method of claim 11, further comprising:completely withdrawing control elements in only the first type of control cell during the final quarter of the operating cycle. 19
    [15] 15. The method of claim 11, Wherein the loading the inner periphery creates the firsttype of control cell including at least two fresh fuel bundles, and Wherein the loading the inner core creates the second type of control cell including no fresh fuel bundles.
    [16] 16. The method of claim 11, Wherein the loading the inner periphery includes loadingfresh fuel bundles into the inner periphery having a higher fuel enrichment than the at least one fuel bundle of the first type of control cell.
    [17] 17. The method of claim ll, further comprising: removing approximately half of the fuel bundles in the core before the loadings.
    [18] 18. A method of operating a nuclear core having at least two different types of controlcells, With a first type of control cell having a combined reactivity higher than a combinedreactivity of the second type of control cell, and With more second type of control cells than thefirst type of control cells, the method comprising: moving control elements in only the second type of control cell to control reactivity in the core for a plurality of operating days.
    [19] 19. The method of claim 18, further comprising: WithdraWing control elements in the first type of control cell only after approximately 3 GWd/ST.
    [20] 20. The method of claim 18, further comprising:completely withdrawing control elements in only the ñrst type of control cell during the final quarter of the operating cycle. 21
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    US13/531,514|US9583223B2|2012-06-23|2012-06-23|Nuclear reactor core loading and operation strategies|
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